Conditions for the self-catalysed inactivation of carnitine acetyltransferase. A novel form of enzyme inhibition

1. Carnitine acetyltransferase is very rapidly inhibited in the presence of bromoacetyl-(-)-carnitine plus CoA or of bromoacetyl-CoA plus (-)-carnitine. 2. Under appropriate conditions, the enzyme may be titrated with either bromoacetyl substrate analogue; in each case about 1mole of inhibitor is required to inactivate completely 1mole of enzyme of molecular weight 58000+/-3000. 3. Inhibition by bromoacetyl-CoA plus (-)-carnitine results in the formation of an inactive enzyme species, containing stoicheiometric amounts of bound adenine nucleotide and (-)-carnitine in a form that is not removed by gel filtration. This is shown to be S-carboxymethyl-CoA (-)-carnitine ester. 4. The inhibited enzyme recovers activity slowly on prolonged standing at 4 degrees . 5. Incubation with S-carboxymethyl-CoA (-)-carnitine ester causes a slow inhibition of carnitine acetyltransferase. 6. The formation of bound S-carboxymethyl-CoA (-)-carnitine ester by the enzyme is discussed. Presumably the resulting inhibition reflects binding of the ester to both the CoA- and carnitine-binding sites on the enzyme and its consequent very slow dissociation. These observations confirm that carnitine acetyltransferase can form ternary enzyme-substrate complexes; this also appears to be the case with carnitine palmitoyltransferase and choline acetyltransferase.     

Multiple forms of choline acetyltransferase in several species demonstrated by isoelectric focusing

1. The behaviour of choline acetyltransferase from pigeon, guinea-pig, rat and cat brain on isoelectric focusing was studied. 2. Choline acetyltransferase from pigeon and guinea-pig brain showed single peaks with isoelectric points at pH6.6 and 6.8 respectively. Only one molecular form of the enzyme was therefore detected in these species. 3. Three peaks of choline acetyltransferase activities with isoelectric points 7.3-7.6, 7.7-7.9 and 8.3 were obtained with enzyme preparations from rat brain. 4. The separate identities of each of the three forms were confirmed by refocusing. 5. Choline acetyltransferase activity from a high-speed supernatant of rat brain homogenate was distributed similarly to a partially purified enzyme preparation from rat brain in the isoelectric gradient. 6. The enzyme activities from cat brain were separated into two distinct peaks with isoelectric points 7.0 and 8.4, and a possible third peak with isoelectric point 7.6. 7. The two main peaks showed considerable differences in stability on storage, and their identities were confirmed by refocusing. 8. The distribution of the enzyme activities was unaltered by isoelectric focusing in the presence of 3m-urea. 9. The apparent K(m) for choline of choline acetyltransferase from rat, cat and guinea-pig brain was 0.8mm, whereas for the pigeon enzyme it was 0.4mm.     

Isolation and characterization of a homogeneous acid phosphatase from catfish liver

A homogeneous, tartrate-inhibitable acid phosphatase (AcPase) was obtained from the liver of channel catfish (Ictalurus punctatus) by the use of Affi Gel-10-coupled aminohexyltartramic acid affinity chromatography. The enzyme has a molecular weight of 82,500 and is a dimer consisting of two apparently equivalent subunits with subunit weights of 35,000 +/- 3000. Amino acid composition data are presented and compared with those of mammalian acid phosphatases. Data suggest that the enzyme is a metalloacid phosphatase. Catfish liver AcPase exhibits two molecular forms with pI 5.66 and 5.37 which were separated by chromatofocusing. A spontaneous conversion of the less acidic form to a more acidic form was observed and this conversion was accompanied by a decreased sensitivity towards tartrate inhibition.     

Choline acetyltransferase in mammalian synaptosomes: Evidence for an integral membrane-bound form

Choline acetyltransferase activity was detected in extensively washed membranes prepared from rat and guinea pig synaptosomes. When these preparations were treated with the non-ionic detergent Triton X-114 and heated to 37°C to cause phase separation, a significant percentage was found to associate with the detergent-rich phase, indicating that the enzyme might be an integral membrane-bound protein. In guinea pigs receiving septal lesions, a large reduction in both total and in Triton X-114-extractable choline acetyltransferase in hippocampal synaptosomes was observed indicating that the detergent-extracted form is associated with cholinergic nerve terminals. When membrane-bound choline acetyltransferase from lysed, washed synaptosomes was incubated in Triton X-114, 30% of the membrane-associated enzyme could be extracted into the detergent-rich phase. This extraction could be improved by reducing the chloride content of the extraction medium. When the chloride content of synaptosomes, prepared from rat cerebral cortex, was manipulated, by either exposure to γ-aminobutyric acid, muscimol or to a medium containing reduced levels of chloride, the ability of antibodies against choline acetyltransferase to specifically immunolyse (in the presence of complement) the cholinergic synaptosome population was enhanced. These results suggest that the choline acetyltransferase found in the nerve terminal region exists in at least two forms (a soluble and a lipophilic form) which are partially interconvertible. The conversion between the two forms can be influenced by chloride ions.     

Characterization of cyanobacterial ferredoxin-NADP+ oxidoreductase molecular heterogeneity using chromatofocusing

Chromatofocusing has been used as an analytical tool to check preparations of the enzyme ferredoxin-NADP+ oxidoreductase (EC 1.18.1.2) purified in either the presence or absence of the serine protease inhibitor phenylmethylsulfonyl fluoride from the cyanobacterium Anabaena sp. strain 7119. Only one isoelectric species was found when the crude extract was processed in the presence of the protease inhibitor. Nevertheless, when the inhibitor was omitted, four ionic forms of the enzyme--showing apparent pI's in the range 4.3-4.6--were separated after chromatofocusing of the purified preparation. These forms were found to differ in their specific activities, exhibiting, on the other hand, lower values than the single one obtained in the presence of the protease inhibitor. Analysis by acrylamide gel electrophoresis revealed virtually a single main protein band except for the ionic form of pI 4.39, which was clearly resolved into two active components. Except for the more basic form, which seems to be an homodimer of Mr 80,000, all the protein components were found to be monomeric species in the range Mr 33,000-38,000. These results indicate that the molecular heterogeneity of the ferredoxin-NADP+ oxidoreductase purified from the cyanobacterium Anabaena sp. strain 7119 may result from the activity of a protease present in the whole cell homogenates. On the other hand, these data also point out that chromatofocusing should be considered as an effective technique in the isolation and characterization of the different molecular forms of this enzyme.     

Aldose reductase from human skeletal and heart muscle. Interconvertible forms related by thiol-disulfide exchange

Aldose reductase was purified from human skeletal and heart muscle by a rapid and efficient scheme involving Red Sepharose chromatography, chromatofocusing on Pharmacia PBE 94, and hydroxylapatite high pressure liquid chromatography. The scheme afforded homogeneous enzyme, 65% recovery, in 2 days. All muscle samples express aldose reductase but not the closely related aldehyde reductase. Aldose reductase is isolated in one of two forms that are distinguishable by their kinetic patterns with glyceraldehyde as substrate and which are interconvertible by treatment with dithiothreitol. Both forms are capable of catalyzing the reduction of glucose (Km = 68 mM), and both are highly sensitive to inhibition by aldose reductase inhibitors. The reduction of glucose was shown to be nearly stoichiometric with production of sorbitol (92 +/- 2%). Dialysis of aldose reductase in the absence of thiols or NADP converts it into a form that shows markedly different kinetic properties, including very weak catalytic activity toward glucose and insensitivity to aldose reductase inhibitors. This modified form can be converted back into the native form by dithiothreitol. Thiol titration of the two forms of aldose reductase with Ellman's reagent indicated that two thiol groups were lost when the enzyme was dialyzed in the absence of dithiothreitol or NADP.     

The purification and properties of ox liver short-chain acyl-CoA dehydrogenase.

The FAD-containing short-chain acyl-CoA dehydrogenase was purified from ox liver mitochondria by using (NH4)2SO4 fractionation, DEAE-Sephadex A-50 and chromatofocusing on PBE 94 resin. The enzyme is a tetramer, with a native Mr of approx. 162 000 and a subunit Mr of 41 000. Short-chain acyl-CoA dehydrogenases are usually isolated in a green form. The chromatofocusing step in the purification presented here partially resolved the enzyme into a green form and a yellow form. In the dye-mediated assay system, the enzyme exhibited optimal activity towards 50 microM-butyryl-CoA at pH 7.1. Kinetic parameters were also determined for a number of other straight-chain acyl-CoA substrates. The u.v.- and visible-absorption characteristics of the native forms of the enzyme are described, together with complexes formed by addition of butyryl-CoA, acetoacetyl-CoA and CoA persulphide.     

Characterisation of 'fast' and 'slow' forms of bovine heart cytochrome-c oxidase.

We have prepared cytochrome-c oxidase from bovine heart (using a modification of the method of Kuboyama et al. (1972) J. Biol. Chem. 247, 6375-6383) which binds cyanide rapidly, shows no kinetic distinction between the two haems on reduction by dithionite, has a Soret absorption maximum above 424 nm, and has a negligible 'g' = 12' EPR signal. On incubation at pH 6.5 this 'fast' oxidase reverts to the 'slow' ('resting') form characterised by slow cyanide binding, slow reduction of haem a3 by dithionite, a blue-shifted Soret maximum and a large 'g' = 12' signal. Incubation of 'fast' oxidase with formate produces a form of the enzyme with properties almost identical to those of 'slow' oxidase. The kinetics of formate binding to 'fast' oxidase are found to be biphasic, revealing the presence of at least two 'fast' subpopulations in our preparations. Evidence is presented that there is an equilibrium mixture of high-spin and low-spin forms of haem a3 in both 'fast' subpopulations at room temperature. Incubation of 'fast' oxidase with chloride or bromide at pH 6.5 produces forms of oxidase with much lower rates of cyanide binding. Our working hypothesis is that formate mimics a binuclear centre ligand which is present in the 'slow' form of cytochrome oxidase. Although we show that chloride and bromide can also be ligands of the binuclear centre, possibly onto CuB, we can rule out either of these being the ligand present in the 'slow' enzyme. We will argue that the 'fast' and 'slow' forms of oxidase are equivalent to the 'pulsed' and 'resting' forms of oxidase, respectively.     

Chromatofocusing of mammalian estrone sulfate sulfohydrolase activity

Estrone sulfate sulfohydrolase (estrogen sulfatase) activity was solubilized by treatment with Triton X-100 from 105,000 g pellets of guinea pig uterus, testis and brain, as well as from rat liver and human placenta. The solubilized forms were subjected to chromatofocusing in the fast protein liquid chromatography (FPLC) system and on conventional columns packed in our laboratory. The guinea pig tissue pattern was complex. Uterus showed peaks of activity with apparent pI's of 9.11 and 7.6; testis contained 3 peaks with pI's of 9.18, 8.7 and 7.5; brain possessed peaks with pI's of 9.28 and 8.6. In each case the major activity peak was that with pI greater than 9. Rat liver activity chromatofocused as a single peak of apparent pI = 6.87 and the human placental enzyme also showed a single, though broad, peak, of pI = 6.57. This suggests not only that the guinea pig enzyme(s) differs markedly from those of rat liver and human placenta, but that there may be qualitative differences between the forms in the three guinea pig tissues. Chromatofocusing behaviour was not independent of the specific exchange resins and ampholytes utilized. The recovered enzyme activity was fairly stable and it seems that chromatofocusing could be a useful step in purification of the guinea pig enzyme(s), particularly the main form possessing a pI greater than 9.     

Human liver iduronate-2-sulphatase. Purification, characterization and catalytic properties.

Human iduronate-2-sulphatase (EC 3.1.6.13), which is involved in the lysosomal degradation of the glycosaminoglycans heparan sulphate and dermatan sulphate, was purified more than 500,000-fold in 5% yield from liver with a six-step column procedure, which consisted of a concanavalin A-Sepharose-Blue A-agarose coupled step, chromatofocusing, gel filtration on TSK HW 50S-Fractogel, hydrophobic separation on phenyl-Sepharose CL-4B and size separation on TSK G3000SW Ultrapac. Two major forms were identified. Form A and form B, with pI values of 4.5 and less than 4.0 respectively, separated at the chromatofocusing step in approximately equal amounts of recovered enzyme activity. By gel-filtration methods form A had a native molecular mass in the range 42-65 kDa. When analysed by SDS/PAGE, dithioerythritol-reduced and non-reduced form A and form B consistently contained polypeptides of molecular masses 42 kDa and 14 kDa. Iduronate-2-sulphatase was purified from human kidney, placenta and lung, and form A was shown to have similar native molecular mass and subunit components to those observed for liver enzyme. Both forms of liver iduronate-2-sulphatase were active towards a variety of substrates derived from heparin and dermatan sulphate. Kinetic parameters (Km and Kcat) of form A were determined with a variety of substrates matching structural aspects of the physiological substrates in vivo, namely heparan sulphate, heparin and dermatan sulphate. Substrate with 6-sulphate esters on the aglycone residue adjacent to the iduronic acid 2-sulphate residue being attack were hydrolysed with catalytic efficiencies up to 200 times above that observed for the simplest disaccharide substrate without a 6-sulphated aglycone residue. The effect of incubation pH on enzyme activity towards the variety of substrates evaluated was complex and dependent on substrate aglycone structure, substrate concentration, buffer type and the presence of other proteins. Sulphate and phosphate ions and a number of substrate and product analogues were potent inhibitor of form A and form B enzyme activities.     

Ornithine decarboxylase modification and polyamine-stimulated enzyme inactivation in HTC cells.

Ornithine decarboxylase isolated from HTC cells was separated into two distinct charged states by salt-gradient elution from DEAE-Sepharose columns. This charge difference between the enzyme forms was maintained in partially purified preparations, but enzyme form II was observed to change to form I in a time-dependent polyamine-stimulated fashion in crude cell homogenates. The enzyme modification that produces this charge diversity between the alternative enzyme states was further investigated for its role in enzyme activity induction, protein stability and rapid turnover. Inhibition of new protein synthesis by cycloheximide resulted in a much more rapid loss of form I enzyme than of form II, suggesting that during normal enzyme turnover the latter enzyme state may be derived from the former. Culture conditions that favour the stabilization of this usually labile enzyme generally induced an increased proportion of the enzyme in the form II charge state. In particular, inhibitors of synthesis of spermidine and spermine induced the stabilization of cellular ornithine decarboxylase and promoted a marked accumulation in form II. Conversely, polyamines added to the cells in culture induced a very rapid loss in both forms of the enzyme, an effect that could not be attributed merely to an inhibition of new enzyme synthesis. It appears that the polyamines, but not putrescine, may be an essential part of the rapid ornithine decarboxylase inactivation process and that they may function in part by stimulating the conversion of the more stable enzyme form II into the less stable enzyme state, form I.     

A comparison of the resonance Raman properties of the fast and slow forms of cytochrome oxidase

Resonance Raman (RR) spectra of the "rapid" and "slow" forms (Baker et al., 1987) of resting cytochrome oxidase obtained with Soret excitation at 413.1 nm are reported. There are a number of conspicuous differences between the two forms in the high-frequency region of the RR spectrum which involve changes in Raman intensity arising from a blue shift in the Soret maximum of cytochrome a3 upon conversion to the slow form. In the low-frequency region a peak present at 223 cm-1 in the rapid form shifts to 220 cm-1 in the slow form; this peak is assigned as the cytochrome a3 Fe(III)-N(His-Im) stretch. The slow form of the enzyme possesses greater intensity in RR peaks near 1620 cm-1 which have been previously attributed by others to partial photoreduction of the enzyme. We have quantitated the amount of laser-induced photoreduction in these RR spectra by comparison with the spectra of mixed-valence derivatives of the enzyme and find that these 1620-cm-1 features are unreliable indicators of photoreduction. The spectra of the fast- and slow-reacting species in H2O and D2O have been compared. The fast-reacting form exhibits a 4-cm-1 shift, from 223 to 219 cm-1, upon transferring to D2O in a peak which we assign as the cytochrome a3 Fe(III)-N(His-Im) stretch. There is a parallel shift in the feature at 1651 cm-1 due to the C = O stretch of the formyl group of cytochrome a. These deuterium shifts are not observed in the slow form.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mitochondrial acetyl-CoA acetyltransferase in various organs from rat: form patterns and coenzyme-A-mediated modification

The mitochondrial acetyl-CoA acetyltransferase (acetyl-CoA:acetyl-CoA C-acetyltransferase, EC 2.3.1.9), which is involved in the biosynthesis or degradation of ketone bodies, was directly demonstrated in organ extracts applying a two-step chromatography-immunoelectrophoresis method. In liver, the enzyme can be shown in at least three forms: in an unmodified state, designated as AAT, and in the CoASH-modified forms A1 and A2, in amounts of 51.5 +/- 5.0%, 39.4 +/- 4.8% and 9.1 +/- 2.7% (areas of immunoprecipitation), respectively. This pattern, which could not be altered by a treatment with glutathione, resembles that of mitochondrial acetyl-CoA acetyltransferase in extrahepatic tissues. However, the proportion of the unmodified enzyme (AAT) is lower as compared to those in other tissues such as brain (81.5 +/- 4.4%). CoASH-modification and transformation into modified forms, which equal naturally occurring forms, can be demonstrated in vitro with acetyl-CoA acetyltransferase from both liver and brain. Thus CoASH-modification of mitochondrial acetyl-CoA acetyltransferase seems to be a process of general importance.     

Biochemical and immunological properties of different electrophoretic forms of juvenile hormone esterase from Trichoplusia ni (Hübner)

The two major electrophoretic forms (pI 5.5, 5.3) of juvenile hormone esterase were independently isolated from hemolymph of larval Trichoplusia ni. A simple and rapid preparation procedure of poly(ethylene glycol) precipitation, Sephadex gel filtration and chromatofocusing is described. Analytical isoelectric focusing showed only one peak of juvenile hormone esterase activity in the respective purified samples, whereas there were four (two major) such peaks in the hemolymph. The amino acid composition of the two forms was similar. The comparison of peptides obtained after protein fragmentation by cyanogen bromide showed that juvenile hormone esterases A and B were very similar, although definitely not identical, in amino acid sequence. The immunological comparisons of juvenile hormone esterases suggested that the number of polyclonal antibody binding sites on both forms was the same. There were no detected differences between immunoreactive properties of juvenile hormone esterase from the hemolymph of different stages of larval maturation. The influence of the active site of the enzyme on its antigenic properties was studied by immunocompetition. The inactive, heat-denatured juvenile hormone esterase can only partially protect against inhibition of its activity by the antibodies, whereas an organophosphate inhibitor which covalently binds to the catalytic center of the enzyme did not change the immunoreactive properties in comparison to active juvenile hormone esterase from hemolymph. These data show that heat-denatured juvenile hormone esterase has lost at least one or more epitopes, but the catalytic site of the enzyme is distinct from the epitopes.     

Studies on the multiple forms of aminopeptidase A in bovine seminal vesicle secretion

After gel filtration, anion exchange chromatography and chromatofocusing aminopeptidase A (AP-A) of bovine seminal vesicle secretion (VS-S) was found to exist in multiple forms. Depending on the pH used (pH 6.5-8.5) gel filtration of VS-S revealed 1-3 forms of AP-A. At pH 8.5 two dissimilar low-molecular-weight forms of AP-A converted into aggregated high-molecular-weight form. The aggregated AP-A was dissociated into an intermediate form with Triton X-100 and/or sodium deoxycholate and further into two low-molecular-weight forms with thiol compounds and neuraminidase. The aggregated, intermediate and low-molecular-weight forms of AP-A displayed some differences in catalytic properties, modifier characteristics and thermal inhibition.     

Characterization of ligand-induced states of maize homoserine dehydrogenase

The threonine-sensitive homoserine dehydrogenase (L-homoserine: NAD(P)+ oxido-reductase), isolated from seedlings of Zea mays L., is characterized by variable kinetic and regulatory properties. Previous analysis of this enzyme suggested that it is capable of ligand-mediated interconversions among four kinetically distinct states (S. Krishnaswamy and J. K. Bryan (1983) Arch. Biochem. Biophys. 222, 449-463). These forms of the enzyme have been identified and found to differ in oligomeric configuration and conformation. In the presence of KCl and threonine a rapid equilibrium among three species of the enzyme (B, T, and K) is established. Each of these species can undergo a unique slow transition to a steady-state form under assay conditions. Results obtained from gel-filtration chromatography and sucrose density centrifugation indicate that the B and steady-state forms are tetramers and the T and K states are dimers. Evidence is presented to indicate that the rapid conversion from one dimeric species to the other can only occur via formation of the tetrameric B state. Chromatography under reacting-enzyme conditions provides direct support for the slow formation of a common steady-state species from any one of the other forms of the enzyme. The rate of transition is influenced by threonine, homoserine, NAD+, and, for transitions involving association reactions, by enzyme concentration. Small, reproducible differences in the apparent size of the T and K forms, and the B and steady-state species, are attributed to changes in conformation. This conclusion is supported by differential susceptibility of the enzymic states to proteolytic inactivation, by different rates of inactivation by dithio-bis-nitrobenzoate, and by alterations in their thermal stability. In addition, the B, T, and K states of the enzyme exhibit unique intrinsic fluorescence spectra. Spectral changes are shown to closely parallel changes in kinetic and hysteretic properties of the enzyme. The results of diverse methods of analysis are internally consistent, and provide considerable support for the conclusion that this pleiotropic regulatory enzyme can exist in any of several physically distinct states.     

Cytosolic aspartate aminotransferases from different chicken tissues: purification and characterization of their multiple forms

Cytosolic aspartate aminotransferases from chicken heart, liver, spleen, skeletal muscle and breast muscle differed in number of their molecular forms, detected by polyacrylamide gel electrophoresis and specific staining. The number of molecular forms varied from tissue to tissue but the electrophoretic mobilities of a given form in all tissues were analogous. Within a single tissue most of the enzyme activity was present as the lowest-running band (alpha form) and the rest was distributed in minor bands termed (B,tau, alpha and epsilon forms). We report a method for the purification of cytosolic aspartate aminotransferases from various chicken tissues. The procedure can be carried out in one week and allows the obtention of isolated molecular forms of the enzyme, independently of the tissue under study. Separation of multiple forms was also achieved by chromatofocusing. The isoelectric points determined by this method for a given form in all five tissues were analogous and differed from those of the molecular forms of the enzyme from other origins. An Mr of 100,000 was obtained for all molecular forms of the five chicken tissues studied.     

Structures of human alcohol and aldehyde dehydrogenases

Human alcohol dehydrogenase is a dimeric zinc metalloenzyme for which forms of three classes, I, II and III, have been distinguished. Subunits hybridize within but not between classes. There are three types of subunit, alpha, beta, and gamma, in class I. The primary structures of all three forms have been established, as well as the overall properties and the effects of the amino acid substitutions between the various forms. Each subunit has 374 residues, of which 35 exhibit differences among the alpha, beta and gamma chains. Corresponding cDNA structures are also known, as are the genetic organization and details of the gene structures. Allelic variants occur at the beta and gamma loci. Corresponding amino acid substitutions have been characterized, and enzymatic differences between the allelic forms are explained by defined residue exchanges. The results also illustrate recent and repeated isozyme evolution, a subject where alcohol dehydrogenases exceptionally well offer detailed examples. Human aldehyde dehydrogenase occurs of two types, a mitochondrial and a cytosolic form. The enzymes are tetramers, do not contain functional metals, and have subunits which do not form inter-type hybrids. The primary structures have been determined, revealing a positional identity of 68% (in 500 residues) between the mitochondrial and cytosolic forms. The N-terminus is heterogeneous and is not blocked in the subunit of the mitochondrial enzyme, in contrast to that of the cytosolic enzyme or those of all the alcohol dehydrogenases (also cytosolic). A reactive cysteine residue at position 302 has been ascribed functional importance at or close to the active site, is conserved in the two aldehyde dehydrogenases, and is associated with the action of disulfiram on the enzyme. In Oriental populations, a mutant allelic variant of the mitochondrial protein with impaired enzyme function has also been characterized.     

PectinaseAspergillus sp. polygalacturonase: Multiplicity, divergence, and structural patterns linking fungal, bacterial, and plant polygalacturonases

Nine forms ofAspergillus sp. polygalacturonase were purified from a commercial preparation of pectinase Rohament P using chromatographies and chromatofocusing. Individual forms differ in isoelectric point, and at least five differ in structure; whereas molecular masses and enzymatic properties are largely identical. Four forms with freea-amino groups have identical start positions but internal amino acid replacements. Therefore, the multiplicity is derived from true heterogeneities and not from N-terminal truncations. Peptide analysis of the major polygalacturonase reveals large variations toward the enzyme from otherAspergillus species (72–75% residue differences, depending on species) but additional similarities with the enzyme from bacterial and plant sources (only 66–71% residue differences toward theErwinia, tomato, and peach enzymes). Combined with previous data, these facts show polygalacturonase to exhibit extensive multiplicity and much variability, but also unexpected similarities between distantly related forms with conserved functional properties     

PectinaseAspergillus sp. polygalacturonase: Multiplicity,divergence, and structural patterns linking fungal,bacterial, and plant polygalacturonases

Nine forms ofAspergillus sp. polygalacturonase were purified from a commercial preparation of pectinase Rohament P using chromatographies and chromatofocusing. Individual forms differ in isoelectric point, and at least five differ in structure; whereas molecular masses and enzymatic properties are largely identical. Four forms with freea-amino groups have identical start positions but internal amino acid replacements. Therefore, the multiplicity is derived from true heterogeneities and not from N-terminal truncations. Peptide analysis of the major polygalacturonase reveals large variations toward the enzyme from otherAspergillus species (72–75% residue differences, depending on species) but additional similarities with the enzyme from bacterial and plant sources (only 66–71% residue differences toward theErwinia, tomato, and peach enzymes). Combined with previous data, these facts show polygalacturonase to exhibit extensive multiplicity and much variability, but also unexpected similarities between distantly related forms with conserved functional properties